Flow control in formic acid production

The
replacement of fossil fuel is a hot topic these days; a lot of research
has been done towards sustainable fuels. Team FAST, a Dutch multidisciplinary
student team of the Eindhoven University of Technology (TU/e) is working
on an initiative, introducing a revolutionary sustainable fuel called Hydrozine.

Hydrozine is defined as a sustainably produced formic acid. Hydrozine technology
is only sustainable if the entire chain is durable. This means using formic
acid extracted from plants, or mixing carbon dioxide with water using sustainable
electricity to create Hydrozine. Using the latter, team FAST wants to prove
that Hydrozine is a suitable candidate for replacing fossil fuels in applications
in the heavy transport industry (such as buses and generators). For this,
they developed a prototype called ‘REX’.

Application
requirements

REX is a standalone generator using Hydrozine as fuel. An in-house developed
catalyst is used here to convert Hydrozine into hydrogen (H2)
and carbon dioxide (CO2) much easier, more stable and more energy-efficient
than any previous catalyst.

The challenge in this process is to measure the gas mixture containing
H2 and CO2, as this is quite specific. Moreover,
it is very important to measure whether or not gas is produced, otherwise
the formic acid could be piling up in the reactor and make it to overflow.
A reliable measurement is therefore desired.

Important topics

Determine exact gas flow

Efficient testing of parameters

High quality

Accurate and reliable measurement

Process solution

The purpose of the ‘REX’ system is to turn Hydrozine into electricity:
the liquid Hydrozine (HCOOH) is stored in the ‘REX’ system at atmospheric
level and subsequently pumped into a reformer. Here the in-house developed
catalyst is used to convert the Hydrozine into the gases hydrogen (H2)
and carbon dioxide (CO2). The hydrogen and carbon dioxide flow
towards a fuel cell where they react with oxygen from the air, which results
in the generation of electricity.

Water vapour and carbon dioxide are being emitted into the air after
the electricity is extracted, which are the same components that are used
to create Hydrozine. This completes the circle in making this energy carrier
carbon neutral.

The REX system has been equipped with Bronkhorst thermal mass flow meters
(IN-FLOW series) as it is desired to measure
the amount of gas being produced. Knowing the gas flow provides information
about how quickly gas is being converted by the system and thus information
about the amount of power which can be generated. In this way different
parameters can be tested to improve the efficiency.

“Bronkhorst had the expertise of this particular gas and was able to
provide us with the right parts and support. The Bronkhorst mass flow meters
are of high quality and made it possible to accurately measure the gas
production, which was not possible for us before. We could even measure
the difference between the formic acid that goes in and the gases that
came out. As the difference between this should be zero, the Bronkhorst
flow sensor was the only one which could actually prove this”.

“Without Bronkhorst we were not able to test the system. So
great thanks to them, for enabling our testing process during the summer!”
according to Team FAST.